TECHNICAL FIELD
[0001] The present invention relates to a sodium chloride electrolytic cell provided with
a gas diffusion electrode. More particularly, the present invention relates to a sodium
chloride electrolytic cell provided with a gas diffusion electrode which allows oxygen
gas to come in good contact therewith.
BACKGROUND ART
[0002] A gas diffusion electrode is normally used as an oxygen electrode for fuel cell or
electrolysis of sodium chloride and is internally composed of a gas supply layer and
a reaction layer.
[0003] The outline of the function and structure of a gas diffusion electrode is described
below taking as an example an oxygen cathode to be used as a cathode in the ion exchange
membrane process electrolysis of sodium chloride. In general, the ion exchange membrane
process electrolysis of sodium chloride involves electrolysis in an electrolytic cell
comprising an anode chamber and a cathode chamber divided by a cation exchange member,
the anode chamber being provided with an anode and filled with an aqueous solution
of sodium chloride and the cathode chamber being provided with a cathode and filled
with an aqueous solution of caustic soda. One of these ion exchange membrane process
sodium chloride electrolytic cells is an electrolytic cell comprising as a cathode
a gas diffusion electrode which supplies a gas containing oxygen, i.e., oxygen cathode.
This type of an electrolytic cell comprises a cathode chamber provided with a gas
supply chamber and composed of a gas diffusion electrode arranged to supply an oxygen-containing
gas onto the cathode therefrom and an electrolytic solution chamber filled with an
aqueous solution of caustic soda.
[0004] In this arrangement, the use of a gas diffusion electrode arranged to supply an oxygen-containing
gas onto the cathode (gas diffusion electrode made of a porous material which supplies
an oxygen-containing gas from the gas supply chamber, hereinafter simply referred
to as "oxygen cathode") in electrolysis in the electrolytic cell involving energization
across the gap between the anode and the cathode gives an advantage that the reduction
reaction of oxygen by hydrogen takes place on the oxygen electrode to lower the cathode
potential, remarkably lowering the required electrolysis voltage.
[0005] The oxygen cathode comprises a thin layer mainly composed of a porous conductor.
In the oxygen cathode, the conductor layer is hydrophobic on the gas supply chamber
side while the conductor layer is hydrophilic on the electrolytic solution side. Further,
the cathode is air-permeable as a whole. Moreover, the cathode is permeable to electrolytic
solution on the electrolytic solution side conductor layer. The electrolytic solution
side conductor layer in contact with the electrode electrolytic solution, e.g., aqueous
solution of caustic soda in the case of electrolysis of sodium chloride, is internally
provided with a collector made of a metal gauze.
[0006] In general, the foregoing porous conductor is mainly made of carbon black. The porous
conductor comprises a catalyst made of a noble metal such as platinum supported thereon
in the pores. The oxygen cathode is made of a water-repellent porous thin layer which
causes no leakage of electrolytic solution on the oxygen-containing gas supply side
thereof. The foregoing water-repellent porous thin layer is normally prepared by forming
a mixture of a particulate fluororesin-based polymer resistant to redox reaction and
water-repellent carbon black.
[0007] The foregoing porous thin layer having such a catalytic activity has an integrated
structure obtained by forming a mixture of hydrophobic carbon, water-repellent carbon
and particulate fluororesin such that the composition of the layer shows a stepwise
change from the hydrophilic surface in contact with the electrolytic solution to the
water-repellent porous thin layer on the gas supply chamber side. Accordingly, the
porous oxygen cathode can efficiently supply an oxygen-containing gas from the oxygen-containing
gas supply side to the side in contact with the electrolytic solution. Further, the
electrolytic solution can easily penetrate and diffuse into the electrode from the
side in contact with the electrolytic solution but doesn't leak into the gas supply
chamber.
[0008] Thus, in the presence of sodium ion supplied from the side in contact with the electrolytic
solution and the foregoing catalyst, water is oxidized in the oxygen cathode to hydroxyl
group, producing caustic soda.
[0009] Further, unlike the earlier process of electrolysis of an aqueous solution of sodium
chloride free from oxygen cathode involving the production of hydrogen at the cathode,
the foregoing electrolysis process using an oxygen cathode is not liable to production
of hydrogen, making it possible to lower the electrolysis voltage.
[0010] Thus, the outline of the function and structure of the oxygen cathode (gas diffusion
electrode arranged to supply an oxygen-containing gas) used in an ion exchange membrane
process sodium chloride electrolytic cell has been described. The outline of the function
and structure of an ordinary gas diffusion electrode is similar to that described
above.
[0011] In the case where a gas diffusion electrode is used as an oxygen cathode in the conventional
ion exchange membrane type sodium chloride electrolytic cell, a liquid-impermeable
gas diffusion electrode is normally used to form a three-chamber structure. In practical
sodium chloride electrolytic cells, e.g., vertical electrolytic cell having a height
as great as 1.2 m or more, electrolysis is conducted with the electrolytic solution
chamber filled with the electrolytic solution. Thus, the gas diffusion electrode is
subject to liquid pressure developed by the electrolytic solution at the lower portion
thereof. In other words, the liquid pressure on the upper portion of the gas diffusion
electrode in the vicinity of the surface of the electrolytic solution in the cathode
chamber is closed to atmospheric pressure, but the liquid pressure on the lower portion
of the gas diffusion electrode in the vicinity of the bottom of the cathode chamber
is the sum of atmospheric pressure and liquid pressure based on the height of the
electrolytic solution (liquid head).
[0012] When the vertical electrolytic cell is provided with a gas diffusion electrode as
oxygen cathode and is then supplied with the electrolytic solution, the gas diffusion
electrode is subject to a great liquid pressure at the lower portion thereof but is
subject to little liquid pressure at the upper portion thereof, making a pressure
differential between the two portions. This pressure differential causes liquid leakage
from the catholyte chamber to the gas chamber at the lower portion of the gas diffusion
electrode. When the liquid pressure and the gas pressure are adjusted equal to each
other at the lower portion of the catholyte chamber to prevent liquid leakage, the
gas pressure in the gas diffusion electrode is higher than the liquid pressure at
the upper portion of the catholyte chamber, causing the leakage of gas into the electrolytic
solution at the upper portion of the gas diffusion electrode.
[0013] Further, when operation is conducted with the liquid pressure being higher than the
gas pressure, if the gas diffusion electrode is not highly water-resistant and sufficiently
sealed, the electrolytic solution leaks into the gas chamber in a large amount, inhibiting
the supply of gas and hence deteriorating the electrode performance and life. In particular,
the use of a gas diffusion electrode having a low resistance to water pressure is
restricted.
[0014] As shown in Fig. 6, the cathode chamber in the foregoing conventional electrolysis
chamber comprises a sheet-shaped gas diffusion electrode 31 placed on a cathode metal
gauze 32 mounted on a cathode chamber frame (not shown). In this arrangement, when
a pressure is applied to the gas diffusion electrode 31 at the caustic chamber 33
side thereof, the gas diffusion electrode 31 is pressed against the cathode metal
gauze 32 to come in contact with the cathode metal gauze 32 so that it is electrically
discharged. At the same time, oxygen is directly supplied into a gas chamber 34 formed
between the cathode chamber frame and the gas diffusion electrode 31, and then taken
into the interior of the electrode from the back side thereof. In Fig. 6, the reference
numeral 35 indicates an ion exchange membrane, and the reference numeral 36 indicates
an anode.
[0015] However, the gas chamber in the foregoing conventional gas diffusion electrode is
preferably configured to comprise existing elements as much as possible to attain
economy when this gas diffusion electrode is applied to actual size electrolytic cell.
In the case where such a gas diffusion electrode is mounted on a cathode metal gauze
as an existing element, the entire space (gas chamber) in the existing cathode element
is an oxygen chamber.
[0016] On the other hand, the higher the linear rate at which oxygen comes in contact with
the oxygen gas diffusion electrode is, the higher is the diffusion rate of oxygen
into the electrode.
[0017] Accordingly, since the existing element has a thickness of from 40 to 50 mm and hence
a great inner capacity, oxygen needs to be supplied in an amount far greater than
calculated to give an oxygen gas linear rate required to cause oxygen to be sufficiently
diffused into the gas diffusion electrode, giving poor economy. It is also disadvantageous
in that even when oxygen is sufficiently supplied, further remodeling is required
to give an arrangement such that oxygen flows uniformly to come in uniform contact
with the surface of the gas diffusion electrode in the existing element.
DISCLOSURE OF THE INVENTION
[0018] The present invention has been worked out in view of these problems with the conventional
techniques. Accordingly, an object of the present invention is to provide a sodium
chloride electrolytic cell comprising a gas diffusion electrode containing a gas chamber
for exclusive use, rather containing an existing element as a gas chamber, the gas
chamber being provided with a gap allowing a linear rate required to cause oxygen
to be sufficiently diffused into the electrode and arranged such that oxygen can come
in uniform contact with the gas diffusion electrode.
[0019] Then, in order to obtain a sodium chloride electrolytic cell which can attain the
foregoing objects, the inventors made extensive studies on the structure of a gas
chamber arranged to allow oxygen to come in uniform contact with the gas diffusion
electrode.
[0020] The inventors made extensive studies on solution to the foregoing problems. As a
result, the following knowledge was obtained.
[0021] The electrolytic solution and oxygen gas are separately supplied into the electrolytic
cell at the upper portion thereof in such a manner that the electrolytic solution
and oxygen gas show the same pressure to make no pressure differential between on
the electrolytic solution chamber side and on the gas chamber side. The electrolytic
solution thus supplied is then allowed to flow down. As a result, the catholyte and
gas flow down with little or no pressure differential therebetween. Accordingly, the
catholyte cannot leak into the gas chamber even in a gas diffusion electrode comprising
a gas supply layer having a small resistance to water pressure.
[0022] However, when operation is conducted with both the anolyte and catholyte being subjected
to atmospheric pressure, the pressure developed by the head of the anolyte presses
and brings the ion exchange membrane into contact with the reactive layer in the gas
diffusion electrode, occasionally preventing the catholyte from running. It was then
found that the foregoing trouble can be effectively prevented by taking an arrangement
such that a hydrophilic porous material which is permeable to electrolytic solution,
can hold electrolytic solution, is little liable to bubbling and cannot be deformed
by the pressure developed by the head of the electrolytic solution and thus cannot
cut the passage is provided interposed between the ion exchange membrane and the reactive
layer in the gas diffusion electrode.
[0023] The inventors made further extensive studies of solution to the foregoing problems.
As a result, it was found that the foregoing problem can be solved by providing, as
a spacer for securing the passage of oxygen, a nickel mesh substance in a concave
gas chamber defined by a cathode frame of thin nickel plate having a concave portion
formed by press molding and a gas diffusion electrode. Thus, the present invention
has been worked out.
[0024] In other words, in the present invention, the foregoing problems can be solved by
the following means:
[0025] 1. A sodium chloride electrolytic cell comprising, as a space for securing a passage
of oxygen, a nickel mesh substance internally fitted in a gas chamber defined by a
gas diffusion electrode and a concave portion having the same size as said gas diffusion
electrode formed in the central portion of a thin nickel plate by press-molding the
thin nickel plate, wherein said nickel mesh substance is shaped to have a large number
of fine corrugations running in the direction perpendicular to a stream of oxygen
so that oxygen is agitated by the corrugations to come in uniform contact with said
gas diffusion electrode.
[0026] In other words, the present invention concerns a gas diffusion electrode comprising,
as a spacer for securing the passage of oxygen, a nickel mesh substance internally
fitted in the gas chamber, and sodium chloride electrolytic cells comprising these
gas diffusion electrodes.
[0027] Preferred examples of the electrolytic cell to which these gas diffusion electrodes
can be specifically applied are described below.
[0028] In a first embodiment of the sodium chloride electrolytic cell as shown in Fig. 1,
a cathode portion 2 in an electrolytic cell 1 comprises an ion exchange membrane 3,
a cathode chamber 4 as an electrolytic solution passage through which the electrolytic
solution flows down, a reactive layer 6 on a gas diffusion electrode 5 which acts
as an oxygen cathode, a gas supply layer 7, and a gas chamber 8. Provided inside the
cathode chamber 4 through which the electrolytic solution flows down is a hydrophilic
porous material 10 having fine open cells. An aqueous solution of caustic soda 11
is supplied into the cathode chamber 4 at a caustic soda inlet 12, and then flows
down from the upper portion of the cathode chamber 4 through the hydrophilic porous
material 10.
[0029] An oxygen gas 14 is supplied into the gas chamber 8 in the gas diffusion electrode
5 at an oxygen gas inlet 15 provided on the upper portion of the gas diffusion electrode
5 at almost the same pressure as in the cathode chamber 4. The amount of the electrolytic
solution flowing down through the cathode chamber 4 is controlled by the pore diameter
and porosity of the hydrophilic porous material 10 and the thickness of the passage.
[0030] As the material constituting the hydrophilic porous material 10 there may be used
any metal, metal oxide or organic material so far as it is resistant to corrosion
and hydrophilic. The hydrophilic porous material 10 is preferably in the form of longitudinally
grooved material, porous material or network arranged to facilitate the downward flow
of the electrolytic solution and hence give little increase in the liquid resistance
during electrolysis. It is particularly important that the hydrophilic porous material
10 have a shape such that bubbles can hardly reside therein.
[0031] The surface of the reactive layer 6 of the gas diffusion electrode 5 is preferably
hydrophilic so that bubbles cannot reside therein. The gas diffusion electrode 5 employable
herein may be either permeable or impermeable to liquid.
[0032] It is important that there be no difference between the pressure of the electrolytic
solution in the cathode chamber 4 as the passage of electrolytic solution and the
pressure of gas in the gas chamber 8 in the gas diffusion electrode 5 . As a means
for accomplishing this purpose there is preferably used a means involving the enhancement
of the gas pressure in the gas chamber 8 in the gas diffusion electrode 5. In this
arrangement, the resulting gas pressure presses the electrolytic solution in the cathode
chamber to restrict the downward flow of the electrolytic solution so that the electrolytic
solution forms a liquid level at the lower end of the cathode chamber 4 in Fig. 1.
[0033] In this case, it is not necessary that an oxygen pressure corresponding to the head
of the electrolytic solution column in the cathode chamber be applied. In practice,
a sodium chloride electrolytic cell comprising an ion exchange membrane is arranged
such that the gap between the ion exchange membrane and the surface of the reactive
layer 6 of the gas diffusion electrode 5, i.e., the thickness of the cathode chamber
is as small as possible, that is, from about 2 mm to 3 mm to minimize the electrical
resistance of the electrolytic cell. Accordingly, the flow resistance developed when
the electrolytic solution flows down increases due to the viscosity of the electrolytic
solution, etc., preventing the entire head of the electrolytic solution column from
directly covering the lower end of the cathode chamber. Therefore, a gas pressure
almost corresponding to the head of the electrolytic solution column covering the
lower end of the cathode chamber may be applied. If the entire head of the electrolytic
solution column directly covers the lower end of the cathode chamber, and the corresponding
gas pressure is applied, the gas leaks from the gas diffusion electrode to the cathode
chamber at the upper end of the cathode chamber as previously described.
[0034] Further also by arranging the cathode such that the electrolytic solution can freely
flow out at the end of the cathode chamber 4 as electrolytic solution passage, there
can be easily no difference between the pressure of electrolytic solution and the
gas pressure.
[0035] In this case, no liquid reservoir is formed at the lower end of the cathode chamber
4. Therefore, even if the cathode chamber 4 is filled with the electrolytic solution
which is flowing down, the head of electrolytic solution column doesn't act on the
electrolytic solution itself.
[0036] In other words, in normal cases, there is provided as a discharge pipe a riser communicating
to the lower end of the cathode chamber 4 from which the catholyte overflows or there
is provided a throttling valve on the discharge pipe provided at the lower end of
the cathode chamber 4 in order to keep the liquid level at the upper end of the cathode
chamber 4. In either case, the head of electrolytic solution column acts on the electrolytic
solution itself.
[0037] When there is provided a free discharge end as previously mentioned, the cathode
chamber 4 through which the electrolytic solution flows down is filled with the electrolytic
solution which is flowing down. The energy developed by the velocity of downward flow
is consumed by the resistance with the ion exchange membrane which the electrolytic
solution contacts. Thus, the static pressure developed by the stationary state doesn't
act on the ion exchange membrane. However, the cathode chamber 4 is always filled
with the electrolytic solution only when the thickness of the cathode chamber 4 is
considerably small as previously mentioned, making it possible to form a continuous
liquid layer.
[0038] By communicating the electrolytic solution and the oxygen gas to each other at the
lower end of the cathode chamber 4, the pressure of the electrolytic solution at the
lower portion of the cathode chamber 4 and the pressure of oxygen gas at the lower
portion of the gas chamber can be easily made equal to each other.
[0039] In a second embodiment, an electrolytic solution reservoir 17 is provided at the
upper portion of the electrolytic cell 1 so that there occurs no pressure differential
between the liquid chamber and the gas chamber. The gas phase above the liquid level
in the electrolytic solution reservoir 17 and an oxygen gas inlet 15 are communicated
to each other through a pipe 18. Further, the upper portion of the electrolytic solution
reservoir 17 and the lower chamber 20 of the electrolytic cell are communicated to
each other through an overflow pipe 21 via a head generator 22 so that the overflowing
electrolytic solution flows down to the lower chamber 20 of the electrolytic cell
through the overflow pipe 21 (see Fig. 2) .
[0040] Thus, the electrolytic solution and the oxygen gas 14 are kept at almost the same
pressure. The electrolytic solution and the oxygen gas are separately supplied into
the electrolytic cell at the upper portion thereof. Then, the electrolytic solution
spontaneously flows down while the oxygen gas comes out from the oxygen gas outlet
16 through a discharge pipe 23 provided at the lower portion of the gas chamber. Since
the catholyte and the gas spontaneously flow down with little pressure differential
therebetween, the catholyte cannot leak to the gas chamber 8 even if a gas diffusion
electrode 5 comprising a gas supply layer 7 having a low water resistance is used.
[0041] However, when the operation is effected with both the anolyte and the catholyte being
subject to atmospheric pressure, the resulting head pressure of the catholyte presses
and brings the ion exchange membrane 3 into contact with the reactive layer 6 of the
gas diffusion electrode 5, preventing the catholyte from flowing. In order to avoid
this trouble, an arrangement is provided such that a hydrophilic porous material which
is permeable to electrolytic solution, can hold electrolytic solution, is little liable
to bubbling and cannot be deformed by the pressure developed by the head of the electrolytic
solution and thus cannot cut the passage is provided interposed between the ion exchange
membrane 3 and the reactive layer 6 of the gas diffusion electrode.
[0042] By forming grooves having a depth of from 0.5 to 4 mm and a width of from 0.5 to
4 mm on the electrolytic solution passage and/or reactive layer 6, the flow rate of
electrolytic solution and gas can be increased. The amount of the electrolytic solution
flowing down can be controlled by changing the height of the liquid level in the electrolytic
solution reservoir 17.
[0043] Fig. 2 illustrates the structure of an electrolytic cell intended to secure electrical
conductivity and gas passage. A bubbler 24 is provided at the gas and electrolytic
solution outlet so that the cathode chamber 4 is compressed by the resulting liquid
pressure. In this arrangement, the pressure in the cathode chamber 4 is higher than
that in the anolyte chamber, causing the ion exchange membrane to be pressed against
the anode and hence allowing electrolysis without any spacer. In this case, the gas
diffusion electrode 5 and the ion exchange membrane 3 are preferably hydrophilic.
[0044] The electrolytic solution reservoir 17 is provided at the upper portion of the electrolytic
cell 1 shown in Fig. 2. The gas phase above the liquid level in the electrolytic solution
reservoir 17 and the oxygen gas thus supplied 14 are communicated to each other through
a gas communicating pipe 18. The upper portion of the electrolytic solution reservoir
17 and the lower portion of the electrolytic cell 1 are communicated to each other
through an overflow pipe 21 so that only the overflowing electrolytic solution flows
down through the electrolytic solution passage provided at the lower portion of the
cathode chamber. If the overflow pipe 21 is directly connected to the lower chamber
20, the chamber of the electrolytic solution reservoir 17 and the lower chamber 20
are kept at the same pressure. Therefore, if the pressure developed by the liquid
column in the cathode chamber 4 is applied to the lower chamber 20, the overflow pipe
21 is preferably connected to the lower chamber 20 through the head generator 22 so
that it is connected to the lower chamber 20 with a head pressure corresponding to
that pressure being applied to the system.
[0045] An embodiment of the gas chamber in the gas diffusion electrode according to the
invention is described below in connection with the drawings. Fig. 3 is a schematic
vertical sectional view illustrating the entire structure of the gas chamber in the
gas diffusion electrode according to the invention. Fig. 4. is a vertical sectional
view illustrating an essential part of the gas chamber of Fig. 3. Fig. 5 is a perspective
view illustrating the structure of the corrugated mesh of Fig 4. Where the same parts
are the same as those of Fig. 6, which illustrates a conventional gas diffusion electrode,
the same numbers are used.
[0046] The oxygen cathode 40 to be used as a cathode in the electrolysis of sodium chloride
using the ion exchange membrane process according to the invention comprises a gas
chamber 34 formed between the gas diffusion electrode 31 and a thin nickel plate 38
having a concave portion 39 having the same dimension as the gas diffusion electrode
31 formed by press-molding as shown in Figs. 3 and 4. In the gas chamber 34 is internally
fitted a nickel mesh substance 37 as a spacer for securing the passage of oxygen.
The mesh substance 37 may be a metal gauze or a stack of metal gauzes. The mesh substance
37 is configured to have a large number of fine corrugations running in the direction
perpendicular to the stream of oxygen so that oxygen is thoroughly agitated by the
corrugations to come in uniform contact with the gas diffusion electrode 31. The mesh
substance 37 needs to have a thickness of from 0.1 to 5 mm to secure the desired flow
velocity of oxygen and lower the resistance.
[0047] The term "mesh substance" as used herein is not a general term. However, since the
term "metal gauze", which is normally used, means a restricted structure and can hardly
encompasses "corrugated mesh" in its scope, the term "mesh substance" is used in the
invention.
[0048] Since the same numbers are used where the parts have the same function as the cathode
chamber in the conventional electrolytic cell described in Fig. 6, repeated description
of those parts is omitted.
[0049] The gas chamber in the gas diffusion electrode according to the invention is configured
as mentioned above. Accordingly, in the case where sodium chloride is electrolyzed
in an electrolytic cell comprising the gas diffusion electrode according to the invention,
the linear velocity of oxygen gas flowing through the mesh is raised because the mesh
is internally fitted in the gas chamber, inevitably reducing the inner capacity of
the gas chamber. At the same time, oxygen gas is thoroughly agitated by the corrugated
mesh so that it can come in uniform contact with the gas diffusion electrode. In this
manner, sufficiently satisfactory oxygen reduction reaction takes place on the gas
diffusion electrode, lowering the cathode potential and hence remarkably lowering
the required electrolysis voltage. In particular, when a corrugated mesh- is used,
the linear velocity of oxygen gas flowing therethrough is further enhanced. At the
same time, oxygen gas is thoroughly agitated by the corrugated mesh, making it possible
for oxygen gas to come in uniform contact with the gas diffusion electrode.
BRIEF DESCRIPTION OF THE DRAWINGS
[0050]
Fig. 1 is a sectional diagram illustrating an embodiment of the electrolytic cell
according to the present invention.
Fig. 2 is a sectional diagram illustrating an embodiment of the electrolytic cell
according to the present invention comprising an electrolytic solution reservoir provided
therein.
Fig. 3 is a sectional diagram illustrating an embodiment of the entire structure of
the gas chamber in the gas diffusion electrode according to the invention.
Fig. 4 is a sectional diagram illustrating an essential part of the structure of the
gas chamber in the gas diffusion electrode according to the invention.
Fig. 5 is a perspective view illustrating the corrugated mesh structure of the nickel
mesh substance shown in Fig. 4.
Fig. 6 is a sectional diagram illustrating an embodiment of the structure of the gas
chamber in the conventional gas diffusion electrode.
BEST MODE FOR CARRYING OUT THE INVENTION
[0051] The present invention will be described in greater detail with reference to the following
Examples. However, the present invention should not be construed as being limited
to these examples. Throughout the Examples, all the "parts" and "%" are meant to indicate
"parts by weight" and "% by weight", respectively.
EXAMPLE 1 (does not fall within the scope of the present invention)
[0052] To 5 parts (hereinafter by weight) of particulate silver (Ag-3010, produced by Mitsui
Mining & Smelting Co., Ltd.; average particle diameter: 0.11 µm) were added 1 part
of Triton as a surface active agent and 9 parts of water. The mixture was then subjected
to dispersion by means of an ultrasonic disperser. To the dispersion thus prepared
was then added 1 part of PTFE dispersion (D-1, produced by DAIKIN INDUSTRIES, LTD.).
The mixture was then stirred. To the mixture were then added 2 parts of ethanol. The
mixture was then stirred so that it was self-organized. The resulting precipitate
was filtered through a filter paper having a pore diameter of 1 µm to obtain a slurry.
[0053] To a silver-plated nickel foamed product (produced by Japan Metals & Chemicals Co.,
Ltd.; thickness: 3.7 mm; size: 10 cm x 20 cm) into which a paste obtained by adding
PTFE dispersion (D-1, produced by DAIKIN INDUSTRIES, LTD.) as gas supply layer had
been previously pushed was then applied the foregoing slurry to a thickness of 0.3
mm. The slurry was then pressed into the foamed product under a pressure of 10 kg/cm
2 to form a reactive layer and a gas supply layer therein. The foamed product was then
dried at a temperature of 80°C for 3 hours. The surface active agent was then removed
by an extractor with ethanol. The foamed product was then dried at a temperature of
100°C for 2 hours to obtain a gas diffusion electrode. The amount of particulate silver
used was 430 g/m
2.
[0054] The gas diffusion electrode thus obtained was then mounted on a silver-plated electrode
frame. A 50 ppi (number of pores per inch) nickel foamed product having a thickness
of 1.5 mm was then laminated on the electrode to form an electrolytic solution passage.
[0055] The gas diffusion electrode thus obtained was mounted in an ion exchange membrane
electrolytic cell shown in Fig. 1. The anolyte pressure was then kept at a water-gauge
pressure of 100 mm so that the gas diffusion electrode was allowed to come in contact
with the nickel foamed product as electrolytic solution passage. A 32% aqueous solution
of caustic soda was allowed to flow down from the upper portion of the electrolytic
cell at a rate of 50 ml per minute. Oxygen gas was allowed to flow through the gas
chamber at almost the same pressure as the aqueous solution of caustic soda in an
amount of 1.5 times the theoretical value. Thereafter, electric current was supplied
into the electrolytic cell.
[0056] As a result, when a 32% aqueous solution of NaOH was supplied at a temperature of
90°C, an electrolytic cell voltage of 2.05 V with a current density of 30 A/dm
2 was obtained. The electrolytic solution which had flown down through the passage
joined excess oxygen gas, and then was discharged from the electrolytic cell at the
lower outlet.
EXAMPLE 2 (does not fall within the scope of the present invention)
[0057] A gas diffusion electrode made of carbon having silver supported thereon was prepared.
The gas diffusion electrode thus prepared was mounted on a gas chamber having a nickel
mesh laminated thereon. A micromesh produced by Katsurada Expanded Metal Co., Inc.
(0.2 Ni, 0.8-M60, thickness: 1 mm) was then provided interposed between an ion exchange
membrane and the gas diffusion electrode to form an electrolytic solution passage.
The operation was then effected under the same conditions as in Example 4 with a 32%
aqueous solution of caustic soda being allowed to flow down at a rate of 90 ml per
minute. As a result, an electrolytic cell voltage of 2.11 V was obtained when the
operation was effected with a 32% aqueous solution of NaOH at a current density of
30 A/dm
2 and a temperature of 90°C with oxygen being supplied in an amount of 1.6 times the
theoretical value.
EXAMPLE 3 (does not fall within the scope of the present invention)
[0058] A gas diffusion electrode made of carbon having platinum supported thereon was prepared.
The gas diffusion electrode thus prepared was mounted on a gas chamber having a nickel
mesh laminated thereon. A corrugated nickel micromesh (0.2 Ni, 0.8-M30, thickness:
1 mm) was then provided interposed between an ion exchange membrane and the gas diffusion
electrode to form an electrolytic solution passage. The operation was then effected
under the same conditions as in Example 4 with a 32% aqueous solution of caustic soda
being allowed to flow down at a rate of 120 ml per minute. As a result, an electrolytic
cell voltage of 2.06 V was obtained when the operation was effected with a 32% aqueous
solution of NaOH at a current density of 30 A/dm
2 and a temperature of 90°C with oxygen being supplied in an amount of 1.6 times the
theoretical value.
EXAMPLE 4 (does not fall within the scope of the present invention)
[0059] An electrolytic cell was provided comprising an electrolytic solution reservoir provided
at the upper portion thereof, the gas phase above the liquid level in the electrolytic
solution reservoir and the gas supplied being communicated to each other through a
pipe, the upper portion of the electrolytic solution reservoir and the lower portion
of the electrolytic cell being communicated to each other through a pipe, as shown
in Fig. 2. In this arrangement, the overflowing electrolytic solution flows down to
the lower portion of the electrolytic cell. No bubbler was provided.
[0060] Referring to the preparation of the gas diffusion electrode used, to 5 parts of particulate
silver (Ag-3010, produced by Mitsui Mining & Smelting Co., Ltd.; average particle
diameter: 0.11 µm) were added 1 part of Triton as a surface active agent and 9 parts
of water. The mixture was then subjected to dispersion by means of an ultrasonic disperser.
To the dispersion thus obtained was then added 1 part of PTFE dispersion (D-1, produced
by DAIKIN INDUSTRIES, LTD.). The mixture was then stirred. To the mixture was then
added 2 parts of ethanol. The mixture was then stirred so that it was self-organized.
The resulting precipitate was filtered through a filter paper having a pore diameter
of 1 µm to obtain a slurry. The slurry was then applied to a silver-plated nickel
foamed product (produced by Japan Metals & Chemicals Co., Ltd.; thickness: 3.7 mm;
size: 10 cm x 20 cm) to a thickness of 0.3 mm to form a reactive layer thereon. To
the foamed product was immediately applied a gas supply layer-forming paste obtained
by adding ethanol to PTFE dispersion (D-1, produced by DAIKIN INDUSTRIES, LTD.). The
PTFE dispersion thus applied was then pressed into the foamed product under a pressure
of 10 kg/cm
2 to form a gas supply layer. The foamed product was then dried at a temperature of
80°C for 3 hours. The surface active agent was then removed from the foamed product
using an extractor with ethanol. The foamed product was dried at a temperature of
80°C for 2 hours, and then subjected to heat treatment at a temperature of 230°C for
10 minutes to obtain an electrode. The amount of particulate silver used was 430 g/m
2.
[0061] The electrode thus obtained was then mounted on a silver-plated electrode frame having
a gas chamber. An ion exchange membrane was then provided interposed between the electrodes
to assemble an electrolytic cell. The anolyte pressure was then kept at a water-gauge
pressure of 100 mm so that the gas diffusion electrode was allowed to come in contact
with the nickel foamed product as electrolytic solution passage. A 32% aqueous solution
of caustic soda was allowed to flow down from the upper portion of the electrolytic
cell at a rate of 50 ml per minute. Oxygen gas was allowed to flow through the gas
chamber at almost the same pressure as the aqueous solution of caustic soda in an
amount of 1.5 times the theoretical value. The resulting waste gas was released to
the atmosphere.
[0062] As a result, when a 32% aqueous solution of NaOH was supplied at a temperature of
90°C, an electrolytic cell voltage of 2.05 V with a current density of 30 A/dm
2 was obtained.
EXAMPLE 5 (does not fall within the scope of the present invention)
[0063] An electrolytic cell was provided having the same structure as that of Example 4
but comprising a bubbler provided at the gas and electrolytic solution outlets by
which the cathode chamber is compressed under liquid pressure.
[0064] A gas diffusion electrode made of hydrophilic carbon black having silver supported
thereon (AB-12), hydrophobic carbon black (No. 6) and PTFE dispersion (D-1, produced
by DAIKIN INDUSTRIES, LTD.) was then mounted on the electrolytic cell with a nickel
corrugate which acts as a gas chamber to assemble an ion exchange membrane process
electrolytic cell. The bubbler used was arranged to have a depth of 40 cm. A 32% aqueous
solution of caustic soda was supplied at a rate of 200 ml per minute. The excess electrolytic
solution was allowed to overflow.
[0065] The operation was effected under the same conditions as in Example 4. As a result,
an electrolytic cell voltage of 1.96 V was obtained when the operation was effected
with a 32% aqueous solution of NaOH at a current density of 30 A/dm
2 and a temperature of 90°C with oxygen being supplied in an amount of 1.6 times the
theoretical value.
EXAMPLE 6
[0066] Using gas diffusion electrodes of the invention having the structures shown in Figs.
3 and 4, tests were conducted with the following specification of electrolytic cell
under the following operating conditions. As a result, an electrolysis voltage of
as remarkably low as 2.01 V was required.
Dimension of reaction area: 100 x 600 mm (reaction area: 75 dm2)
Anode: DSE (produced by Permelec Electrode Ltd.)
Cathode: Gas diffusion electrode
Ion exchange membrane: Flemion 893 (produced by Asahi Glass Co., Ltd.)
Electrolysis current density: 30 A/dm2
Operating temperature: 90°C
Caustic concentration: 32 wt-% NaOH
Sodium chloride concentration: 210 g/1·NaCl
INDUSTRIAL APPLICABILITY
[0067] The gas diffusion electrode according to the invention comprises as a spacer for
securing the passage of oxygen, a nickel mesh substance provided in an extremely thin
flat box-shaped gas chamber formed between a cathode frame made of thin nickel plate
having a concave portion formed by press-molding and the gas diffusion electrode.
Thus, the gas chamber has a reduced inner capacity that enhances the linear rate of
oxygen gas flowing through the mesh and causes oxygen gas to be thoroughly agitated
by the mesh. The use of the foregoing gas diffusion electrode makes it possible to
allow oxygen to come in uniform contact with the gas diffusion electrode. Accordingly,
extremely good oxygen reduction reaction takes place on the gas diffusion electrode,
lowering the cathode potential and hence remarkably lowering the required electrolysis
voltage.